Alkalosis – Causes, Symptoms, Diagnosis, Treatment

Alkalosis is excessive blood alkalinity caused by an overabundance of bicarbonate in the blood or a loss of acid from the blood (metabolic alkalosis), or by a low level of carbon dioxide in the blood that results from rapid or deep breathing (respiratory alkalosis). Alkalosis is excessive blood alkalinity caused by an overabundance of bicarbonate in the blood or a loss of acid from the blood (metabolic alkalosis), or by a low level of carbon dioxide in the blood that results from rapid or deep breathing (respiratory alkalosis).

Alkalosis is an abnormal pathophysiological condition characterized by the buildup of excess base or alkali in the body. It results in an abnormally high serum pH (arterial pH greater than 7.45), which is termed alkalemia and forms one end of the spectrum of acid-base disorders. There is generally a loss of hydrogen ions (H) or an excess of bicarbonate ions (OH), and multiple factors can cause either of these. In general, alkalosis is less life-threatening than acidosis, but severe electrolyte derangements can accompany alkalosis due to transcellular shifts, potentially resulting in rare but severe clinical disorders. Alkalosis can be either respiratory or metabolic in origin, but metabolic alkalosis is far more common than respiratory causes. This activity reviews the evaluation and management of alkalosis and highlights the interprofessional team’s role in improving care for patients with alkalosis.

Alkalosis is an abnormal pathophysiological condition characterized by the buildup of excess base or alkali in the body. It results in an abnormally high serum pH (arterial pH greater than 7.45), which is termed alkalemia and forms one end of the spectrum of acid-base disorders. There is generally a loss of hydrogen ions (H) or an excess of bicarbonate ions (OH), and multiple factors can cause either of these. In general, alkalosis is less life-threatening than acidosis, but severe electrolyte derangements can accompany alkalosis due to transcellular shifts, potentially resulting in rare but severe clinical disorders. Alkalosis can be either respiratory or metabolic in origin, but metabolic alkalosis is far more common than respiratory causes.

Causes of Alkalosis

The etiology of alkalosis can subdivide into metabolic and respiratory causes:

Metabolic

  • Excess loss of hydrogen ion—this occurs primarily due to gastric losses (prolonged and severe gastric aspiration, excessive emesis of gastric contents as in pyloric stenosis, congenital chloridorrhea).
  • Increased bicarbonate in the extracellular compartment—this occurs due to excess enteral intake of bicarbonate or alkali (milk-alkali syndrome) or increased parenteral intake of nitrate or acetate. Increased renal reabsorption of bicarbonate can also cause metabolic alkalosis (severe hypokalemia, primary hyperaldosteronism, Cushing syndrome, Bartter syndrome, Gitelman syndrome, toxic ingestion of licorice, excessive chloruretic diuretic use).
  • Diuretic-induced alkalosis—diuretics (loop and thiazide) that block sodium and chloride reabsorption can cause increased bicarbonate absorption at the proximal tubule leading to increased serum bicarbonate concentration, also called contraction alkalosis.

Respiratory

  • Low production of CO2—hypometabolic conditions like severe coma, particularly when supported by mechanical ventilation.
  • Excess pulmonary loss of CO2—this results in alkalosis when the production of CO2 in the body is normal (psychogenic hyperventilation, iatrogenic hyperventilation in patients on assisted mechanical ventilation or extracorporeal membrane oxygenation, early stages of salicylate overdose due to overstimulation of the respiratory center).

The body has a robust buffering system that acts to minimize pH change in the initial stages of acid-base derangements. When these buffering systems are overwhelmed, alkalosis may result.

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The kidney attempts to maintain normal acid-base balance by the dual mechanisms of bicarbonate reabsorption, mainly in the proximal tubule, and bicarbonate production in the distal nephron. Reabsorption of bicarbonate is mediated by a Na-H (sodium-hydrogen) antiporter and also by the H (+)-ATPase (adenosine triphosphate-use). Influences on bicarbonate reabsorption include effective arterial blood volume, glomerular filtration rate, chloride, and potassium concentrations in the serum. In conditions resulting in respiratory alkalosis, the kidney acts to both decrease bicarbonate reabsorption and bicarbonate production as a compensatory mechanism. This process helps maintain the pH of the extracellular compartment to neutralize the effect of the low pCO2 that is the primary derangement of respiratory alkalosis. However, the kidneys’ complex buffering mechanisms may take several days to achieve full effect, with an eventual expected fall of bicarbonate by 4 to 5 mmol/L for every 10 mmHg fall in pCO2.

On the other hand, respiratory depression resulting in increased PaCO2 occurs promptly and predictably to buffer the alkalemia resulting from metabolic conditions (while this is variable, expectations are that there will be a 0.5 mmHg increase in PaCO2 per 1 mmol/L increase in HCO). Alkalemia also causes a shift in the oxyhemoglobin dissociation curve towards the left, thus increasing hemoglobin’s affinity for oxygen and decreasing oxygen release to the tissues.

When the intake of potassium is suboptimal, this can correlate with metabolic alkalosis due to intracellular sodium and proton levels rising as well as a consequent depression in aldosterone levels. When protons shift into the cellular compartment, metabolic alkalosis ensues; this is followed by respiratory center depression of respiratory drive and ultimately, the purging of bicarbonate by the kidney.

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Diagnosis of Alkalosis

There are no specific histopathological features that are pathognomonic for alkalosis. However, the primary cause of alkalosis may be established by histopathological studies, especially when related to kidney or adrenal disorders.

History and Physical

Alkalosis can present with a myriad of signs and symptoms, based on the etiology of alkalosis (respiratory versus metabolic) and the primary condition leading to alkalosis.

Metabolic alkalosis can have central nervous system manifestations ranging from confusion to coma, peripheral neuropathic symptoms of tremor, tingling and numbness, muscle weakness and twitching, and arrhythmias, particularly when associated with hypokalemia and hypocalcemia. Nonhypochloremic metabolic alkalosis associates with hypertension and is usually the result of syndromes of excess mineralocorticoid production. These generally correlate with signs of volume expansion, hypertension, and hypokalemia. Persistent and projectile, non-bilious emesis in a two to six-week-old, otherwise well-appearing infant is a hallmark presentation of pyloric stenosis.

Respiratory alkalosis can have associated syncope, tremors, and signs of hyperventilation, along with chest pain and dyspnea.

Lab Test and Imaging

A blood gas analysis, preferably arterial, is needed to establish alkalosis and whether it appears to be metabolic or respiratory in origin. Ancillary blood tests are necessary; these are serum chemistries with electrolytes, blood urea nitrogen, and creatinine. While the bicarbonate concentration being high can indicate the possibility of metabolic alkalosis, it is not confirmatory, as both the carbon dioxide concentration and the concentration of H+ ions will affect the presence or absence of alkalosis. Hence, a blood gas estimate of pH and pCO2 is also needed. However, in mixed acid-base disorders, complex calculations are necessary to establish multiple disturbances and whether they are primary and/or coexistent abnormalities or compensatory buffering mechanisms.

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Associated electrolyte abnormalities need to be identified, including hypochloremia, hypokalemia, and hypocalcemia. An EKG may be necessary to evaluate for arrhythmias. Urine chemistry is required to assess the kidney’s response to alkalosis. Hypertension requires assessment and other tests for hyperaldosteronism when indicated. Volume depletion also requires evaluation as a coexisting condition.

When associated with hypoxia or an increased alveolar-arterial (A-a) gradient, respiratory alkalosis requires a search for a cause of hypoxia. However, pulmonary embolism may cause respiratory alkalosis without associated hypoxia and must be ruled out before attributing hyperventilation to pain or anxiety.

Treatment of Alkalosis

The appropriate management of alkalosis rests on prompt identification followed by management of the primary etiology of the alkalosis and the type of the alkalosis (metabolic, respiratory, or mixed). Specific etiologies like pyloric stenosis need surgical correction, while excessive ingestion of alkali will respond to restriction of excess intake. Alkalosis associated with conditions of excess aldosterone may need hormonal correction or replacement along with the treatment of associated hypertension. Correction of chloride responsive alkalosis caused by volume depletion is possible by replenishment of extracellular volume. Electrolyte disturbances associated with alkalosis such as hypokalemia and hypocalcemia are the chief causes of clinical deterioration in the patient and must undergo correction before the onset of life-threatening complications. Slow acid administration or dialysis with low bicarbonate baths may be necessary for emergent situations.

Treatment of respiratory alkalosis primarily targets correcting the hyperventilation (primary or iatrogenic), and apart from anxiety and pain treatment, it sometimes also requires adjustment of mechanical ventilation with intentional hypercapnia.

Complications

Alkalosis can lead to life-threatening arrhythmias (atrial and ventricular tachyarrhythmias), especially when associated with hypokalemia and hypocalcemia. These associated electrolyte abnormalities can also cause carpopedal spasms, muscle weakness, and altered mental status.

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